基本情况：

物理与电子信息学院教授，粒子物理与原子核物理专业博士，硕士生导师，兼任量子信息与量子光学实验室主任，广西光学学会理事。广西光学学会理事；国际SCI期刊International Journal of Theoretical Physics、Entropy、Quantum Information Processing，国内高水平学术期刊Sci. China Ser. G-Phys. Mech. Astron.审稿人；《中国科学:力学 物理学 天文学》青年编委。以第一作者或通讯作者在中国科学、Journal of Physics A、Physica Scripta、Quantum Information Processing、Journal of the Optical Society of America B 等期刊发表论文40余篇。

  邮 箱：zhouping@gxmzu.edu.cn

研究方向：

量子通信、量子光学、量子计算

主持/参与项目：

(1)光子系统多自由度并行远程量子信息处理研究,2024.1-2027.12, 主持 国家自然科学基金(主持在研).

(2)光量子态远程制备中的物理问题研究,2016.1-2019.12 主持 国家自然科学基金(主持完成).

(3)环境噪音下的远程量子态制备与操控网络研究,2016.1-2018.12 主持 国家自然科学基金(主持完成).

(4)有噪声的量子可控离物传态及其应用,2011.1-2011.12 主持 国家自然科学基金(主持完成).

部分论文（第一作者/第一通讯作者）：

SCI期刊论文

[1]Q. Lan, C. M. Huang and P. Zhou. Parallel remote preparation of quantum states with polarization-frequency-time-bin hyperentangled state. Quantum Inf. Process., 23: 388(2024)；

[2]R. H. Jing, Y. B. Huang, J. Yang, A. A. Bi, J. Y. Zhang, K. B. Xia and P. Zhou*. Deterministic bidirectional hierarchical teleportation of an arbitrary high- dimensional multi-particle state with a partially entangled quantum channel. Eur. Phys. J. Plus, 139: 894 (2024)；

[3]R. H. Jing, Q. Lan and P. Zhou*. Hierarchical controlled joint remote implementation of the partially unknown operations of m qudits with m high-dimensional entangled states. Entropy, 26: 857 (2024)；

[4]R. H. Jing, Y. B. Huang, A. A. Bi, W.W. Luo, P. Zhou* and  Q. Lan. Mentor initialed multiparty hierarchical joint remote preparation of an arbitrary n-qudit state via generalized Bell states. Phys Scr., 99: 025103 (2024)；

[5]M. F. Chen, P. Zhou*, Q. Lan and X. Q. Lu. Hyper-parallel nonlocal CNOT operation assisted by quantum-dot spin in a double-side optical microcavity. JOSA B, 40: 3291 (2023)；

[6]R. H. Jin, W. S. Wei and P. Zhou. Hierarchical controlled remote  preparation of  an arbitrary m-qudit state with four- qudit cluster states. Quantum Inf. Process., 22: 113(2023)；

[7]K.H. Feng, Y. C. Chen and P. Zhou*. Protecting high-dimensional entanglement   from decoherence via quantum weak measurement and reversal. Mod. Phys.  Lett. A, 37: 2250117 (2022)；

[8]X. Q. Lu, K. H. Feng and P. Zhou*. Deterministic remote preparation of an arbitrary single-qudit state with high-dimensional spatial-mode entanglement via linear-optical elements. Int. J. Theor. Phys., 61: 36 (2022)；

[9]Y. H. Li, L. M. He and P. Zhou*. Controlled cyclic remote preparation of an arbitrary single-qudit state by using a seven-qudit cluster state as the quantum channel. Int. J. Theor. Phys., 60: 1635 (2021)；

[10]L. Lv and P. Zhou*. Effect of noise on deterministic remote preparation of an arbitrary two-qudit state by using a four-qudit χ-type state as the quantum channel. Int. J. Quantum Inf., 18: 2050028 (2020);

[11]P. Zhou* and L. Lv. Joint remote state preparation of  single-photon three-qubit state with hyperentangled state via linear- optical elements. Quantum Inf. Process., 19: 283(2020)；

[12]L. M. He, N. Wang and P. Zhou*. Effect of quantum noise on teleportation of an arbitrary single-qubit state via a triparticle W state. Int. J. Theor. Phys., 59: 1081 (2020)；

[13]P. Zhou* and L. Lv. Hyper-parallel nonlocal CNOT operation with hyperentanglement assisted by cross-Kerr nonlinearity. Sci. Rep., 9:15939 (2019);

[14]S. X. Lv, X. F. Jiao and P. Zhou*. Multiparty quantum computation for summation and multiplication with mutually unbiased bases. Int. J. Theor. Phys., 58: 2872 (2019)；

[15]X. F. Jiao, P. Zhou*, S. X. Lv and Z. Y. Wang. Remote preparation for single- photon two-qubit hybrid state with hyperentanglement via linear-optical elements. Sci. Rep., 9: 4663 (2019);

[16]X. F. Jiao, P. Zhou* and S. X. Lv. Remote implementation of single-qubit operations via hyperentangled states with cross-Kerr nonlinearity. JOSA B, 36: 867 (2019)；

[17]P. Zhou*, X. F. Jiao and S. X. Lv. Parallel remote state preparation of arbitrary single-qubit states via linear- optical elements by using hyperentangled Bell states as the quantum channel. Quantum Inf. Process., 17: 298 (2018)；

[18]S. X. Lv, Z. W. Zhao and P. Zhou*. Joint remote control of an arbitrary single-qubit state by using a multiparticle entangled state as the quantum channel. Quantum Inf. Process., 17: 8 (2018)；

[19]S.X. Lv, Z. W. Zhao and P. Zhou*. Multiparty-controlled joint remote preparation of an arbitrary m-qudit state with d-dimensional Greenberger- Horne- Zeilinger states. Int. J. Theor. Phys., 57: 148 (2018)；

[20]J.Y.Lin,J.G.He,Y.C.Gao,X.M.LiandP. Zhou*. Controlled remote implementation of an arbitrary single-qubit operation with partially entangled quantum channel. Int. J. Theor. Phys., 56: 1085 (2017)；

[21]R.F.Yu,Y.J. Lin and P. Zhou*. Joint remote preparation of arbitrary two- and three-photon state with linear-optical elements .Quantum Inf. Process., 15: 4785 (2016)；

[22]Q. C. Lu, D. P. Liu, Y. H. He, Y. M. Liao, X. C. Qin, J. S. Qin and P. Zhou*. Linear-optics-based bidirectional controlled remote state preparation via five- photon cluster-type states for quantum communication network. Int. J. Theor. Phys., 55: 535  (2016)；

[23]Y. H. He, Q. C. Lu, Y. M. Liao, X. C. Qin, J. S. Qin and P. Zhou*. Bidirectional controlled remote implementation of an arbitrary single qubit  unitary operation with EPR and Cluster states. Int. J. Theor. Phys., 54: 1726 (2015)；

[24]Y. M. Liao, P. Zhou*, X. C. Qin and Y. H. He. Efficient joint remote preparation of arbitrary 2-qubit state via cluster and cluster-type states. Quantum Inf. Process., 13: 615 (2014)；

[25]Y. M. Liao, P. Zhou*, X. C. Qin, Y. H. He and J. S. Qin. Controlled remote preparing of an arbitrary two-qudit state with two-particle entanglements and positive operator-valued measure. Commun. Theor. Phys., 61: 315 (2014)；

[26]L. T. Ai, L. Nong and P. Zhou*. Efficient joint remote preparation of arbitrary m-qudit state with partially entangled states. Int. J. Theor. Phys., 53: 159 (2014);

[27]P. Zhou*, H. W. Li  and L. R. Long. Probabilistic multiparty joint remote preparation of an arbitrary m-qubit state with a pure entangled quantum channel against collective noise. Int. J. Theor. Phys., 52: 849 (2013)；

[28]P. Zhou*. Joint remote preparation of an arbitrary m-qudit state with a pure entangled quantum channel via positive operator-valued measurement. J. Phys. A, 45: 215305 (2012)；

[29]Z. Li and P. Zhou*. Probabilistic multiparty-controlled remote preparation of  an arbitrary m-qudit state via positive operator-valued measurement. Int. J.  Quantum Inf., 10: 1250062 (2012);

[30]L. R. Long, P. Zhou*, Z. Li and C. L. Yin. Multiparty joint remote state preparation of an arbitrary GHZ-class state via positive operator-valued measurement. Int. J. Theor. Phys., 51: 2438 (2012)；

[31]Z. Li, L. R. Long, P. Zhou* and C. L. Yin.  Probabilistic multiparty- controlled teleportation of an arbitrary m-qubit state with a pure entangled quantum channel against collective noise. Sci. China Ser. G-Phys. Mech. Astron., 55: 2445-2451 (2012)；

[32]L. R. Long, H. W. Li, P. Zhou*, C. Fan and C. L. Yin. Multiparty - controlled teleportation of an arbitrary GHZ-class state by using a d-dimensional (N+2)- particle nonmaximally entangled state as the quantum channel. Sci. China Ser. G-Phys. Mech. Astron., 54: 484-490 (2011)；

[33]P. Zhou, F. G. Deng and H. Y. Zhou. Probabilistic quantum entanglement swapping and quantum secret sharing with high-dimensional pure entangled systems. Phys. Scr., 79: 035005 (2009)

[34]P. Zhou, X. H. Li, Y. J. Liang, F. G. Deng and H. Y. Zhou. Multiparty quantum secret sharing with pure entangled states and decoy photons. Physica A, 381: 164-169 (2007)

[35]P. Zhou, X. H. Li, F. G. Deng and H. Y. Zhou. Efficient three-party quantum secret sharing with single photons. Chin. Phys. Lett., 24: 2181 (2007)

[36]P. Zhou, X. H. Li, F. G. Deng and H. Y. Zhou. Multiparty-controlled teleportation of an arbitrary m-qudit state with a pure entangled quantum channel. J. Phys. A, 40: 13121 (2007)

[37]P. Zhou, X. H. Li, F. G. Deng and H. Y. Zhou. Probabilistic teleportation of an arbitrary GHZ-class state with a pure entangled two-particle quantum channel and its application in quantum state sharing. Chin. Phys., 16: 2867 (2007)

EI期刊论文:

[1]P. Zhou*, L. Lv and L. M. He. Effect of noise on remote preparation of an arbitrary single-qubit state. Quantum Engineering, 3: e64 (2021)；

核心期刊论文:

[1]陆湘琦,王译柳,陈孟钒,杨真仙,黄翠钰, 周萍*. 基于量子点-双边光学腔的两自由度并行非定域Toffoli门远程实现. 中国科学 物理学 力学 天文学, 52(12): 120314(2022)

[2]冯坤鸿, 陆湘琦, 周萍*. 基于部分纠缠信道的高维多粒子态分等级可控隐形传态. 中国科学 物理学 力学 天文学, 52(3): 230311(2022)

[3]周萍*, 焦显芳. 联合噪声信道下基于部分纠缠态的非定域Toffoli门远程实现. 中国科学 物理学 力学 天文学, 49(7): 070302 (2019)

[4]吕莉，周萍*, 何良明，崔雪鸿. 基于d维六粒子Cluster态的任意qudit态远程联合制备. 中国科学 物理学 力学 天文学, 50(8): 080301 (2020)

[5]黎勇宏，何良明，周萍*. 基于部分纠缠信道的高维赤道态概率可控远程联合制备. 中国科学 物理学 力学 天文学, 51(5): 050301 (2021)

[6]黄平武，周萍*, 农亮勤，何良明，尹彩流. 基于高维两粒子纠缠态的量子超密编码方案. 光子学报, 40: 780 (2011)

[7]李宏伟，龙柳蓉，周萍*,尹彩流. 基于(2m+1)粒子任意多粒子态量子可控远程制备. 光子学报, 40(3): 330-334 (2012)

获奖情况：

(1)2022，获广西科学技术奖（自然科学奖）三等奖, 周萍，何良明，何燕和, “量子态远程制备与隐形传态”.

(2)2022,2021,《中国科学：物理学 力学 天文学》优秀编委奖习.